KR101295342B1 - Smart electronic display control system and method for compensating luminance of led - Google Patents

Abstract

PURPOSE: A smart display board control system and a method thereof, capable of correcting the brightness of respective LEDs are provided to prevent stains that adjacent LEDs appear dark because a brightness value of a specific LED is high at a display board by matching the brightness of a replaced LED with the brightness of the existing adjacent LEDs. CONSTITUTION: A brightness measurement unit (100) generates first brightness measurement data which digitizes the brightness of respective LEDs of a display board. First input data for a lighting time, a flickering time, a power value, and a brightness value in lighting of the respective LEDs of the display board is inputted to an image data input unit. A comparison unit (300) selects one or more first LEDs having brightness values greater than a reference brightness value set in the first brightness measurement data and generates a correction power value for matching the brightness value of the first LED with an average brightness value of second LEDs. An image data correction unit (400) generates second input data by receiving the first input data and the correction power value. [Reference numerals] (10) Display board; (100) Brightness measurement unit; (200) Image data input unit; (300) Comparison unit; (400) Image data correction unit; (500) Driving unit

Description

Smart Electronic Display Control System and Method for Compensating Luminance of LED

The present invention relates to a smart display board control system and method capable of compensating luminance for each LED, and more particularly, after the LEDs are individually replaced by failures of the LEDs in the display board using the LEDs, the luminance of the replaced LEDs is around. The present invention relates to a smart display board control system and method capable of compensating brightness for each LED that can be calibrated to match the brightness of existing LEDs.

In general, when LEDs are replaced individually due to failure of LEDs in LED boards, only the parts of LEDs that are replaced in LEDs are bright because the brightness of the LEDs is higher than that of existing LEDs. There was a problem that looks relatively dark.

In this regard, Korean Patent No. 0898521 discloses an invention for an LED backlight brightness detection system for a liquid crystal display. However, this does not solve the problem of detecting only the brightness of the LED and correcting the brightness of the LED whose brightness does not match. there was.

An object of the present invention devised to solve the problems as described above is to replace the LED individually due to the failure of the LED in the LED board using the LED, the brightness of the replaced LED is consistent with the brightness of the existing LED around the The purpose of the present invention is to provide a smart display board control system and method capable of correcting luminance for each LED that can be corrected.

In addition, when LED dots are individually replaced due to a failure of the LED dots, a smart display board control system capable of luminance correction for each LED, which can correct the luminance of the replaced LED dots to match the luminance of the existing LED dots with surroundings. To provide a method.

According to a feature of the present invention for achieving the object as described above, the smart display board control system capable of brightness correction for each LED of the present invention, by measuring the brightness of each LED of the light plate, and quantified the measured brightness of each LED A luminance measuring unit configured to generate first luminance measurement data; An image data input unit configured to input first input data about a lighting time, a flashing time, a power value supplied at lighting, and a luminance value at lighting of each LED of the electronic board; The luminance measuring unit receives the first luminance measurement data, selects one or more first LEDs whose luminance value is greater than a preset reference luminance value among LEDs whose luminance is numerically calculated from the first luminance measurement data, and selects the selected first A comparator configured to generate a corrected power value for matching the LED to an average brightness value of the second LEDs other than the first LEDs; The second input which receives the first input data from the image data input unit and the correction power value from the comparator, and changes the power value supplied when lighting included in the first input data transmitted to the first LED to the correction power value. An image data correction unit generating data; And a driver configured to transmit second input data transmitted from the image data corrector to the first LED, wherein the luminance measurer measures luminance of each dot of the LED and digitizes the measured luminance of each LED dot. 2 further generates luminance measurement data, and the image data input unit further inputs third input data for the lighting time, the flashing time, the power value supplied when the LED dot is lit, and the luminance value when the LED dot is lit, and the comparator includes the luminance measuring unit. Receives the second luminance measurement data from the second luminance measurement data, selects one or more first LED dots of which the luminance value is greater than the preset reference luminance value among LED dots whose luminance is numerically calculated from the second luminance measurement data, and selects the selected first LED Further generating a correction power value to match the dot with the average brightness value of the second LED dots, the remaining LED dots except the first LED dot, the image data correction unit Fourth input data in which the input unit receives the third input data and the comparator receives the correction power value, and changes the power value supplied during lighting included in the third input data transmitted to the first LED dot to the correction power value. Further generating, wherein the driver further transmits the fourth input data transmitted from the image data correction unit to the first LED dot.

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Smart display panel control method of the present invention comprises the steps of: (a) the image data input unit receives the first input data for the lighting time, the flashing time, the power value supplied when the lighting and the luminance value of each of the LED of the display board; (b) a luminance measuring unit measuring luminance of each LED of the electronic display board and generating first luminance measurement data each of which is measured the luminance of each LED; (c) the comparison unit receives the first luminance measurement data from the luminance measurement unit, and selects one or more first LEDs whose luminance value is greater than a preset reference luminance value among LEDs whose luminance is numerically calculated from the first luminance measurement data; Generating a correction power value for matching the selected first LED with an average luminance value of second LEDs other than the first LEDs; (d) The image data correction unit receives the first input data from the image data input unit and the correction power value from the comparator, and corrects the power value supplied when lighting included in the first input data transmitted to the first LED. Generating second input data changed to a value; And (e) the driver transmitting the second input data transmitted from the image data corrector to the first LED, wherein step (a) includes the lighting time, the flashing time, Further receiving third input data on the power value supplied at lighting and the luminance value at lighting, and in the step (b), the luminance measuring unit measures the luminance of each dot of the LED and digitizes the measured luminance of each LED dot. The second luminance measurement data is further generated, and in the step (c), the comparator receives the second luminance measurement data from the luminance measurement unit, and the luminance value is preset among LED dots whose luminance is numerically calculated from the second luminance measurement data. One or more first LED dots larger than the reference luminance value are selected, and a correction power value is further added such that the selected first LED dot matches the average luminance value of the second LED dots, which are the remaining LED dots except for the first LED dot. In the step (d), the image data correction unit receives the third input data from the image data input unit and the correction power value from the comparator unit, and supplies the light when the third input data is included in the third input data transmitted to the first LED dot. The fourth input data is further generated by changing the power value to the corrected power value, and in step (e), the driver further transmits the fourth input data transmitted from the image data corrector to the first LED dot. .

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According to the present invention as described above, after replacing the LED individually due to the failure of the LED in the LED board using the LED, by the LED can be corrected to match the brightness of the existing LED with the surrounding LED brightness It is possible to provide a smart display board control system capable of luminance correction.

In addition, when LED dots are individually replaced due to a failure of the LED dots, a smart display board control system capable of luminance correction for each LED, which can correct the luminance of the replaced LED dots to match the luminance of the existing LED dots with surroundings. It may provide a method.

1 is a block diagram of a smart display board control system capable of brightness correction for each LED according to a preferred embodiment of the present invention,
2 is a schematic diagram of a smart display board control system capable of brightness correction for each LED according to an embodiment of the present invention,
Figure 3 is a schematic diagram of the brightness of a specific LED is different than other LEDs in the smart sign control system capable of brightness correction for each LED according to a preferred embodiment of the present invention,
Figure 4 is a schematic diagram of the brightness of a specific LED dot is different than other LED dots in the smart sign control system capable of brightness correction for each LED according to an embodiment of the present invention,
5 is a flowchart illustrating a method for controlling a smart signboard capable of compensating luminance for each LED according to a preferred embodiment of the present invention.
6 to 8 are block diagrams further including an error detector, a serial data output (SDO), a shift unit, and a constant current unit in a smart display control system capable of luminance correction for each LED according to an exemplary embodiment of the present invention. ,
9 and 10 are schematic diagrams illustrating an example of generating a luminance correction value in a smart display board control system capable of luminance correction for each LED according to an exemplary embodiment of the present invention.
FIG. 11 is a schematic diagram of a circuit for outputting error data in a smart sign control system capable of luminance correction for each LED according to an exemplary embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to the drawings for explaining a smart display board control system and method capable of luminance correction for each LED according to embodiments of the present invention.

Smart display board control system capable of brightness correction for each LED of the present invention according to a preferred embodiment of the present invention, as shown in Figure 1 and 2, the brightness measuring unit 100, the image data input unit 200, the comparison unit ( 300, an image data corrector 400, and a driver 500.

The luminance measuring unit 100 measures luminance of each LED 600 of the electronic display panel 10, and generates first luminance measurement data in which the luminance of each of the measured LEDs 600 is quantified. As shown in FIG. 2, the luminance measuring unit 100 is spaced apart from the LED by a predetermined distance to measure the luminance of the LEDs 600 of the LED 10.

Here, the range for measuring the brightness may be the entire electronic sign 10 or may be a specific portion of the electronic sign 10.

In addition, the luminance measuring unit 100 measures the input data (color value) from 0 to 255 step by step and stores the measured values as OldBrightTb and NewBrightTb.

The image data input unit 200 receives first input data regarding a lighting time, a flashing time, a power value supplied when the LED 600 of the LED panel 10 is lit, and a luminance value when the LED 600 is turned on.

Here, the lighting time and the flashing time of each of the LEDs 600 in the first input data input to the image data input unit 200 are to be turned on and then flashing when the LED 600 is to implement an image flickering. It's time.

In addition, when the LED 600 is turned on in the first input data input to the image data input unit 200, the power value supplied to the LED 600 and the luminance value at the time of lighting are, for example, when the LED 600 is turned on. The power value supplied when the luminance value of 5 should be emitted.

The comparator 300 receives the luminance measurement data from the luminance measuring unit 100, and excludes the luminance value of the first LED 610 whose luminance is greater than or equal to a preset value from the first luminance measurement data. Second input data including the correction power value to be consistent with the average luminance value of the two.

For example, as shown in FIG. 3, when the luminance value of the first LED 610 is 7 and the average luminance value of the second LEDs 620 is 5, the first LED 610 is the luminance value of 7. Comparing the second input data which is a correction power value for lowering the power value supplied to the first LED 610 to emit a luminance value of 5, which is an average luminance value of the second LEDs 620, when the light is emitted. It means to generate in the unit 300.

9 and 10, the comparison unit 300 compares the luminance value tables OldBrightTb and NewBrightTb to generate a luminance correction value, and generates a luminance correction value for each step from 0 to 255. FIG. Then, the luminance correction value and the input data are bit-calculated together to correct the luminance.

Here, the luminance compensation value generation selects the luminance correction value by comparing the luminance value of OldBrightTb with the luminance value of NewBrightTb and searching for a value near an approximation (integer).

The image data corrector 400 receives the first input data from the image data input unit 200, receives the second input data from the comparator 300, and transmits the first input data to the first input data transmitted to the first LED 610. The third input data is generated by changing the power value supplied at the time of included lighting into the power value of the second input data.

The driver 500 transmits the power value of the third input data transmitted from the image data corrector 400 to the first LED 610.

As such, since the luminance value of the first LED 610 coincides with the average luminance value of the second LEDs 620 through the third input data transmitted to the first LED 610, the specific LED in the electronic display panel 10. A high luminance value of 600 has an advantage of preventing the spots of the surrounding LEDs 600 from appearing dark.

As described above, the smart display board control system capable of luminance correction for each LED may further measure luminance for each LED dot, and perform luminance correction for a specific LED dot having a different luminance from an average luminance value of the LED dots.

As described above, a case in which the luminance can be measured and corrected for each LED dot will be described with reference to FIG. 4.

The luminance measuring unit 100 measures the luminance of each dot of the LED 600, and further generates second luminance measurement data in which the luminance of each of the measured LED dots 630 is digitized.

The image data input unit 200 is further inputted with fourth input data regarding a lighting time, a flashing time, a power value supplied when the LED dot 630 is turned on, and a luminance value when the LED dot 630 is turned on.

The comparator 300 receives the second luminance measurement data from the luminance measuring unit 100, and excludes the luminance value of the first LED dot 631 whose luminance is greater than or equal to a preset value from the second luminance measurement data. The fifth input data is further generated including a correction power value to match the average luminance value of the dots 632.

The image data corrector 400 receives the fourth input data from the image data input unit 200, receives the fifth input data from the comparator 300, and transmits the fourth input data to the first LED dot 631. The sixth input data is further generated by changing the power value supplied at the time of lighting to the power value of the fifth input data.

The driver 500 further transmits a power value of the sixth input data transmitted from the image data corrector 400 to the first LED dot 631.

As such, the luminance value of the first LED dot 631 is equal to the average luminance value of the second LED dots 632 through the sixth input data transmitted to the first LED dot 631. In this case, the luminance value of the specific LED dot 630 is high, so that peripheral LED dots 630 may be prevented from appearing dark.

In addition, since the luminance may be corrected in the unit of the LED dot 630 corresponding to each of the RGB dots in the LED 600 configured as a set of RGB dots, the luminance value of the specific LED 600 having different luminance may be changed. There is an advantage that can be completely matched with the average luminance value of the other LEDs 600 except for the LED (600).

As described above, the smart display board control system capable of compensating luminance for each LED further includes an error detector, a data output unit (SDO), a shift unit, and a constant current unit as illustrated in FIGS. 6 to 8.

As illustrated in FIG. 11, the error detection unit transmits an error for the case where the circuit for each LED dot is disconnected or shorted to the flag register and outputs error data.

As such, the error detection unit is a technology for detecting the state of the LED module in the open-short circuit, and the gray scale correction is possible only when connected to the VCC or GND at the input side of the circuit. In this state, gray scale correction is not possible.

The data output unit transmits the input shift image data to the next LED module input data, and when an error is detected and the error flag of the register is set, an error message is output. When an error occurs, the error data is output through the output pin of the last module output terminal. Outputs

The shift unit controls shift and timing together, and combines serial image data and gray correction values, transmits the corrected image data to the output driver, and sends the error transmitted from the error detection unit of the output terminal to the output data. Process the error data. Here, the gray correction value may be the correction data described above or may be separate data.

The constant current unit receives the converted data from the shift unit and generates a constant current based on the received converted data. The constant current generated in the constant current unit is transmitted to the driving unit to emit the LED dots.

Hereinafter, a smart display board control method capable of compensating luminance for each LED according to an exemplary embodiment of the present invention will be described with reference to FIG. 5. The luminance measuring unit 100, the image data input unit 200, the comparing unit 300, the image data correcting unit 400, and the driving unit 500 described in the smart display board control method capable of luminance correction for each LED are described for each LED. Since the same as the luminance measuring unit 100, the image data input unit 200, the comparator 300, the image data correction unit 400, and the driver 500 of the smart display board control system capable of luminance correction, a description thereof will be omitted. .

As shown in FIG. 5, the smart display board control method capable of luminance correction for each LED may include a first input data input step S100, a first brightness measurement data generation step S200, a second input data generation step S300, and the like. The third input data generation step S400 and the third input data transmission step S500 are included.

In the first input data input step (S100), the image data input unit 200 inputs a first input to a lighting time, a flashing time, a power value supplied at lighting, and a luminance value at lighting of each of the LEDs 600 of the display panel 10. Receive data.

In the first luminance measurement data generation step (S200), the luminance measuring unit 100 measures the luminance of each LED 600 of the display panel 10, and measures the first luminance of each of the measured luminances of the LEDs 600. Generate data.

In the second input data generation step (S300), the comparator 300 receives the luminance measurement data from the luminance measuring unit 100, and the luminance of the first LED 610 whose luminance is greater than or equal to a preset value in the first luminance measurement data. Second input data including a correction power value for matching the average luminance value of the second LEDs 620 excluding the luminance value is generated.

In the third input data generation step (S400), the image data corrector 400 receives the first input data from the image data input unit 200 and receives the second input data from the comparator 300, and thus receives the first LED ( In operation 610, third input data generated by changing the power value supplied when lighting included in the first input data transmitted to the power value of the second input data is generated.

In the third input data transmission step (S500), the driver 500 transmits the power value of the third input data transmitted from the image data corrector 400 to the first LED 610.

As described above, the smart display board control method capable of luminance correction for each LED may further measure luminance for each LED dot, and perform luminance correction for a specific LED dot having a different luminance from an average luminance value of the LED dots.

In this way, the case where the luminance can be measured and corrected for each LED dot will be described.

In the first input data input step (S100), the image data input unit 200 further inputs fourth input data about the lighting time, the flashing time, the power value supplied when the LED dot 630 is turned on, and the luminance value when the LED dot 630 is turned on. Receive.

In the first luminance measurement data generation step (S200), the luminance measuring unit 100 measures luminance of each dot of the LED 600, and measures the luminance of each of the measured LED dots 630. Generate more.

In the second input data generation step (S300), the comparator 300 receives the second luminance measurement data from the luminance measuring unit 100, and the first LED dot having a luminance greater than or equal to a preset value in the second luminance measurement data ( And further generates fifth input data including a correction power value to match the average luminance value of the second LED dots 632 except for the luminance value of 631.

In the third input data generation step (S400), the image data correction unit 400 receives the fourth input data from the image data input unit 200 and the fifth input data from the comparator 300, and thus receives the first LED dot. The sixth input data is further generated by changing the power value supplied during lighting included in the fourth input data transmitted to 631 to the power value of the fifth input data.

In the third input data transmission step (S500), the driver 500 further transmits a power value of the sixth input data transmitted from the image data corrector 400 to the first LED dot 631.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

10: electronic board
100: luminance measuring unit 200: image data input unit
300: comparison unit 400: image data correction unit
500: driving unit 600: LED
610: first LED 620: second LED
630: LED dot 631: first LED dot
632: second LED dot
S100: first input data input step
S200: generating first luminance measurement data
S300: second input data generation step
S400: third input data generation step
S500: third input data transmission step

Claims (4)

delete A luminance measuring unit measuring luminance of each LED of the electronic display board and generating first luminance measurement data each of which is measured numerically;
An image data input unit configured to input first input data about a lighting time, a flashing time, a power value supplied during lighting, and a luminance value during lighting of each LED of the electronic board;
The luminance measuring unit receives first luminance measurement data, and selects one or more first LEDs whose luminance value is greater than a predetermined reference luminance value among LEDs whose luminance is numerically calculated from the first luminance measurement data. A comparator configured to generate a correction power value for matching the first LED with an average brightness value of the second LEDs other than the first LEDs;
The first input data is transmitted from the image data input unit and the correction power value is received from the comparator, and the power value supplied when the light is included in the first input data transmitted to the first LED is converted into the correction power value. An image data corrector configured to generate modified second input data; And
And a driver for transmitting the second input data transmitted from the image data corrector to the first LED.
The luminance measuring unit,
Measuring the luminance of each dot of the LED, and further generating second luminance measurement data each of which is measured the luminance of each of the LED dots,
The image data input unit,
Third input data for the lighting time, the flashing time, the power value supplied at lighting, and the luminance value at lighting of each of the LED dots is further input.
Wherein,
Receiving the second luminance measurement data from the luminance measuring unit, and selecting one or more first LED dots having a luminance value greater than a preset reference luminance value among LED dots whose luminance is numerically calculated from the second luminance measurement data, Further generating a correction power value for matching the selected first LED dot with an average luminance value of second LED dots which are remaining LED dots except for the first LED dot,
The image data correction unit,
The third input data is transmitted from the image data input unit and the correction power value is received from the comparator, and the power value supplied when lighting included in the third input data transmitted to the first LED dot is the corrected power value. Generate the fourth input data changed to
The driving unit includes:
Smart display board control system capable of brightness correction for each LED, characterized in that for further transmitting the fourth input data transmitted from the image data correction unit to the first LED dot.
delete (a) receiving, by the image data input unit, first input data about a lighting time, a flashing time, a power value supplied when the LED is turned on, and a luminance value when the LED is turned on;
(b) a luminance measuring unit measuring luminance of each LED of the electronic display board and generating first luminance measurement data each of which is measured the luminance of each LED;
(c) the comparator receiving first brightness measurement data from the brightness measurement unit, and among the LEDs whose brightness is numerically calculated from the first brightness measurement data, at least one first LED having a brightness value greater than a preset reference brightness value; Selecting and generating a corrected power value such that the selected first LED matches the average luminance value of the second LEDs other than the first LEDs;
(d) power supplied when the image data correction unit receives first input data from the image data input unit and a correction power value from the comparator, and is turned on in the first input data transmitted to the first LED; Generating second input data of which a value is changed to the corrected power value; And
(e) a driving unit transmitting second input data transmitted from the image data correcting unit to the first LED;
The step (a)
The image data input unit further receives third input data regarding a lighting time, a flashing time, a power value supplied when the LED dot is turned on, and a luminance value when the LED dot is turned on.
The step (b)
The luminance measuring unit measures the luminance of each dot of the LED, and further generates second luminance measurement data in which the luminance of each of the measured LED dots 630 is digitized.
The step (c)
The comparator receives second brightness measurement data from the brightness measurement unit, and selects one or more first LED dots of which brightness is greater than a preset reference brightness value among LED dots whose brightness is numerically calculated from the second brightness measurement data. Selects and further generates a correction power value for matching the selected first LED dot with an average luminance value of second LED dots which are remaining LED dots except for the first LED dot,
The step (d)
The image data correction unit receives the third input data from the image data input unit and the correction power value from the comparison unit, and the power value supplied when the light is included in the third input data transmitted to the first LED dot. Generating fourth input data of which is changed to the corrected power value;
The step (e)
And the driver further transmits the fourth input data transmitted from the image data corrector to the first LED dot.

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